AT525932B1 - Organic material removal assembly - Google Patents

Abstract

The invention relates to a sampling assembly (1) for small quantities of body fluids, comprising a sample container (2) and an extension element (3). The sample container (2) has a base (13) and a container wall (5) with a first container wall section (6) and an adjoining second container wall section (7). The second container wall section (7) is hollow-conical and projects into the extension element (3). The sample container (2) is designed as a multi-layer body and comprises at least one barrier layer. Furthermore, a coupling device (25) with a first coupling element (26) and a second coupling element (27) is provided. When the coupling elements (26, 27) are in coupling engagement, the extension element (3) is positively coupled to the sample container (2) in the form of a snap connection to the sampling assembly (1).

Description

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Description

[0001] The invention relates to a collection assembly for blood, body fluids, tissue parts or tissue cultures or organic material, which receiving device comprises a tube-shaped sample container and, with usual standard dimensions of length and diameter, usually comprises a so-called "false bottom", wherein the "false bottom" can be formed by an extension element, wherein the extension element can be coupled to the sample container.

[0002] A similarly designed sampling assembly for receiving a small amount of a sample is known from EP 1 382 394 A1. The sampling assembly comprises a first upper tube and a second lower tube, as well as a closure device. The two tubes are dimensionally almost identical to one another, but are made of a different material. Each of the tubes comprises a first tube section and an adjoining second tube section, which are hollow-cylindrical in design and are connected to form a unit by means of a connecting section. In the end section of each tube opposite the open end, the second hollow-cylindrical tube section is provided, which is inserted into the open end and thus into the first tube section of the other tube to form the sampling assembly.

[0003] Furthermore, the document EP3618962 A1 and WO 2018/201174 A1 disclose a collection assembly for small quantities of body fluids, comprising a sample container and an extension element. The sample container has a base and a container wall with a first container wall section and an adjoining second container wall section. The second container wall section is hollow-conical and projects into the extension element. Furthermore, a coupling device with a first coupling element and a second coupling element is provided. When the coupling elements are in engagement, the extension element is positively coupled to the sample container in the form of a snap connection to the collection assembly. The document also discloses that the inner surface of the sample container and, if appropriate, also the base of the sample container with its base surface facing the collection chamber can be provided with a coating for treating the filled sample.

[0004] Furthermore, the documents EP2110174 A1, EP0787821 A2, EP0789092 A2, US5019243 A, WO2009117129 A2 and EP2065184 A1 disclose sample containers or receiving containers which have a multi-layer structure, wherein the multi-layer structure comprises at least one barrier layer.

[0005] The object of the present invention was to overcome the disadvantages of the prior art and to provide a sampling assembly with improved barrier properties of the sample container while at the same time enabling the entire sampling assembly to be manufactured more economically.

[0006] This object is achieved by a device according to the claims.

[0007] The device according to the invention relates to a collection assembly for receiving a small amount of a body fluid, in particular a blood sample, urine, saliva.

[0008] The sampling assembly comprises a sample container with a container wall, which container wall extends from a first open end to a second end, is delimited by an outer surface and an inner surface and defines a longitudinal axis, and with a bottom, which bottom closes the second end of the container wall and, together with the container wall, defines a collection space. In this case, the container wall comprises, in the direction of the longitudinal axis, a first container wall section and an adjoining second container wall section. The first container wall section is hollow-cylindrical with a first outer diameter dimension and is arranged starting from the open end. The second container wall section has, with respect to the first outer diameter dimension

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The first container wall section has, at least in sections, a second diameter dimension that is smaller than the first diameter dimension. A transition section is arranged between the first container wall section and the second container wall section.

[0009] Furthermore, the removal assembly comprises an extension element with a side wall, which side wall extends from a first open end to a second end, and with a bottom wall arranged adjacent to the second end, wherein the bottom wall of the extension element is dome-shaped, in particular hollow spherical dome-shaped.

[0010] In the assembled state or coupled state of the removal assembly, the sample container projects at least partially into the first open end of the extension element with its second container wall section arranged at a distance from the first open end in the direction of the longitudinal axis.

[0011] Furthermore, the removal assembly comprises a coupling device with at least one first coupling element and with at least one second coupling element, wherein the at least one first coupling element is arranged or formed on the sample container and the at least one second coupling element is arranged or formed on the extension element, and wherein.

[0012] When the first and second coupling elements are in coupling engagement, the extension element is positively coupled to the sample container to the removal assembly by means of a snap connection formed by the coupling elements.

[0013] The second container wall section of the container wall of the sample container is hollow conical, wherein the at least one first coupling element is arranged in the transition section between the first container wall section and the second container wall section of the container wall.

[0014] The side wall of the extension element is formed as a hollow cylinder between the first open end and the second end, wherein the side wall, viewed in axial section, is formed as continuous and straight between the first open end of the extension element and the second end of the extension element.

[0015] According to the invention, the sample container comprises a first layer made of a first plastic material. The first plastic material can be selected from the group of polymers, which group includes PE, HD-PE, PET, or PP, or another polymer with equivalent technical properties.

[0016] Furthermore, the sample container has at least one second layer made of a second plastic material. The second plastic material can be selected from the group comprising ethylene-vinyl acetate or EVOH, PP, polyolefin, cycloolephine copolymer or cycloolephine polymer, or a polymer with equivalent technical properties.

[0017] The second layer is a barrier layer and has a first layer thickness, wherein the first layer thickness originates from a layer thickness range whose lower limit is 0.01 mm, in particular 0.05 mm, and whose upper limit is 0.9 mm, in particular 0.2 mm.

[0018] A barrier layer is understood to be a wall of the sample container designed in such a way that it has advantageous properties with regard to inhibiting the diffusion of certain substances through the second layer or through the interaction of the second layer with the first layer or another layer. It is conceivable that a liquid additive with a water content is present in the collection space of the sample container even before a sample is taken and even during storage of the previously unused sample container. Thus, the second layer made of the second plastic material can, among other things, in combination with the first layer or on its own, have a particularly diffusion-inhibiting effect on oxygen and similar gases or substances, so that the liquid additive and/or a sample in the collection space is technically sealed or advantageously sealed with a diffusion-inhibiting effect. At the same time, the combination of the first layer and the second layer or one of the two layers can have a diffusion-inhibiting effect on water and substances or gases, since the first plastic material in particular has hydrophobic properties.

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properties. The diffusion-inhibiting properties of the barrier layer, or in this case the second layer in conjunction with the first layer, provide improved protection against environmental influences and degradation of the contents of the sample container. Among other advantages, this extends the storage time and shelf life of the contents of the sample container in the collection chamber, and ensures improved quality of the contents of the sample container over a longer period of time compared to a single-layer sample container.

[0019] In the region of the transition section, the second layer of the sample container has a second layer thickness. The second layer thickness originates from a layer thickness range whose lower limit is 0.01 mm, in particular 0.025 mm, and whose upper limit is 0.5 mm, in particular 0.1 mm. In the region of the transition section, the second layer is completely covered by the first layer or another layer on a second surface facing away from the first coupling element. In any case, contact of the sample or of the contents of the sample container with the barrier layer or with the second layer is thus excluded.

[0020] By providing a separate coupling device, a mutual, positively locking and fastening of the extension element to the sample container can be created. The additional hollow-conical design of the second container wall section allows the design and arrangement of the individual coupling elements to be optimized in terms of shape engineering. Furthermore, the selection of the hollow-conical second container wall section also enables a central injection point in the area of the bottom of the sample container. A central injection point has the advantage that the first and second plastic materials can be introduced rotationally symmetrically during the molding or forming of the sample container using an injection process or similar manufacturing process. Furthermore, the selection of positively locking coupling elements can prevent material accumulation on the sample container and on the extension element, thereby achieving more uniform cooling times. Furthermore, warping, the occurrence of internal stresses, air inclusions, or cavities can be avoided. This allows both the sample container and the extension element to be manufactured in their own cavities and each designed with an optimal component geometry. The respective cavities can be arranged either in separate injection molds or in a shared injection mold. The use of a rotary cube tool would also be possible. In addition, after the simultaneous production of the sample container and extension element, the assembly to form the removal assembly could also take place immediately, particularly in an automated manner. Using the coupling device, the sample container and the extension element can then be coupled together to form a cohesive unit, which reliably prevents accidental detachment from one another due to the mutual positive retention.

[0021] If the bottom wall of the extension element is dome-shaped, in particular hollow spherical dome-shaped, a bottom geometry adapted to conventional centrifuging devices is created in the bottom area.

[0022] Since the at least one first coupling element is arranged in a transition section between the first container wall section and the second container wall section of the container wall, it is possible to design the sample container and the extension element with approximately the same outer dimensions to each other, in order to achieve a consistently identical, in particular rectilinear, outer surface in the coupled state of the sample container with the extension element.

[0023] If the side wall of the extension element is hollow-cylindrical, in particular continuous and straight between the first open end and the second end, the continuous straight design of the side wall creates an extension element that is simple and inexpensive to manufacture. Furthermore, this also allows the attachment of at least one label to the outer surface of the sample container and the extension element.

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ment is facilitated and improved. This is especially true when, viewed in axial section, a straight transition is formed between the outer surfaces of the sample container and the extension element.

[0024] Furthermore, it may be expedient if the second layer in the region of the transition section is fully covered by the first layer or another layer on a first surface facing the first coupling element. Thus, the barrier layer or the second layer or the second plastic material is fully or completely encapsulated by the first layer or by the first plastic material or enveloped by the first layer, thereby significantly improving the barrier properties of the sample container. The interaction of the fully enclosed second layer and the first layer reduces both oxygen and water diffusion into and out of the collection space of the sample container, and the diffusion inhibition is improved compared to a single-component sample container. At the same time, the vacuum properties of the sample container are retained by using the first plastic material as the carrier material. Furthermore, it is ensured that the coupling device retains its unrestricted functionality, since the outer surface of the sample container is formed from the first plastic material.

[0025] Furthermore, it can be provided that the sample container has an average or mean total wall thickness, which originates from a wall thickness range whose lower limit is 0.5 mm, in particular 0.9 mm, and whose upper limit is 1.5 mm, in particular 1.1 mm. It is advantageous that, with the above-mentioned dimensioning of the barrier layer or the second layer in the region of the constriction by the coupling device, a continuous and complete barrier layer is nevertheless formed, wherein at the same time the second layer has an average layer thickness, which ensures the most economical manufacturability of the sample container. This is particularly noteworthy since the second plastic material incurs additional costs in the manufacturing process compared to the first plastic material.

[0026] According to the invention, it is further provided that the container wall of the sample container is designed as a multi-barrier layered body, wherein the second layer is formed continuously and coherently within the container wall of the sample container, wherein the second layer is completely encased by the first layer or the second layer is embedded in the first layer and is formed directly connected to the first layer or is molded onto it. It is advantageous that the first and second plastic materials have a material bond or that the first and second plastic materials are formed with a material bond in contact surfaces between the first and second plastic materials, whereby, while simultaneously improving the diffusion inhibition of the sample container, the collection space remains visible from the outside to ensure optical sample inspection or analysis.

[0027] Furthermore, it may be expedient for the container wall to be manufactured from the first layer and the at least one second layer using a two-component co-injection process. This allows the advantageous barrier properties of the sample container to be achieved in a single manufacturing step, resulting in improved mutual bonding or molding of the first and second plastic materials. Thus, the encapsulation of the second layer is fully formed by the first layer. Furthermore, producing the multi-layer sample body in a single operation offers economic advantages in terms of cycle times.

[0028] Also advantageous is an embodiment according to which it can be provided that the sample container is produced by means of an overmolding or overmolding process from a blank that is overmolded or overmolded with the second layer or with the second layer and the first layer, wherein the blank has the inner surface of the sample container and is formed from the first plastic material starting from the inner surface relative to the longitudinal axis radially towards an increasing diameter.

[0029] It is also conceivably advantageous if, during the production of the sample container by means of

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A two-component co-injection process or multi-component injection molding, or an overmolding process, where an adhesion promoter or a technically equivalent auxiliary material is used between the first and second layers, or where an adhesion promoter is formed between the first and second layers. This achieves an improved form fit or material bond between the first and second layers, which in turn enhances the previously described technical advantages over a single-component sample container.

[0030] Furthermore, it can be provided that the second layer is formed within a first wall thickness section of the container wall, which first wall thickness section is closest to the longitudinal axis in the radial direction with respect to the container wall or is the inner section of the container wall with respect to the collecting space. It is advantageous that, when the sample container is manufactured by injection molding, the barrier layer continues to be uniform, continuous, and coherent from the constriction in the coupling device towards the first open end of the sample container and is embedded in the first plastic material. Thus, an advantageous barrier effect or improved diffusion inhibition is achieved by the multilayer body thus formed, particularly in the region of the constriction or the first groove in the coupling device and further towards the open end of the sample container.

[0031] Furthermore, it can be provided that the first wall thickness section extends from the inner surface of the sample container radially to the longitudinal axis in the direction of the outer surface, wherein the first wall thickness section has a wall thickness that originates from a wall thickness range whose lower limit is 25% of the total wall thickness of the sample container and whose upper limit is 80% of the total wall thickness of the sample container, wherein the wall thickness of the first wall thickness section is, in particular, 40% of the total wall thickness of the sample container. This advantageously ensures that the second layer is also continuous in the region of the coupling device, which results in advantageous barrier properties.

[0032] According to a particular embodiment, it is possible for the second layer to be circumferentially closed in the region of the bottom of the sample container, with the first layer completely sealing the collection chamber from the second layer, and with the first layer completely sealing the area surrounding the sample container from the second layer. It is advantageous that the second plastic material is completely encased in the region of the bottom, which provides improved long-term protection for the sample and/or liquid additives in the collection chamber.

[0033] According to an advantageous development, it can be provided that in the region of the first open end of the sample container, the second layer is completely encased by the first layer, wherein in the region of an end face of the first open end of the sample container, the first layer has a layer thickness of at least 0.3 mm. Thus, the barrier layer is completely encased in the region of the closure device, which improves the sealing properties with respect to the closure device.

[0034] In particular, it may be advantageous if the at least one first coupling element is designed as a first groove extending around the circumference and the wall section of the side wall of the sample container adjoining it in the direction of the bottom of the sample container. This eliminates the need for additional material accumulation to form the coupling element. Furthermore, this also reduces the joining effort, since prior mutual orientation is only necessary and can be carried out in axial alignment with one another. Furthermore, this does not impede the continuous formation of the barrier layer, and the advantageous diffusion-inhibiting properties of the multi-layer sample container are retained.

[0035] Furthermore, it can be provided that a first side surface of the first groove facing the open end of the sample container forms a stop surface for an end face of the extension element in the region of its first open end, and the first side surface

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forms an axial stop for the first end face of the extension element. This creates secure mutual support in the axial direction between the sample container and the extension element. This is particularly important when supporting the extension element during a centrifugation process. It can also be advantageous if the first side surface has a transition radius to the groove base, so that a continuous transition in the thickness of the wall thickness of the sample container is formed. This ensures that turbulence in the barrier layer can be minimized as much as possible during the production process of the sample container, subsequently forming an advantageous, continuous and closed barrier layer.

[0036] Furthermore, it can be provided that a second side surface of the first groove, facing away from the open end of the sample container, forms a stop surface for a second groove of the extension element in the region of its first open end, and the second side surface forms an axial stop for the second groove of the extension element. This creates secure mutual support in the axial direction between the sample container and the extension element. This is particularly important when supporting the extension element during a centrifugation process. It can also be advantageous if the second side surface has a transition radius to the groove base, so that a continuous transition of the thickness of the wall thickness of the sample container is formed. This ensures that turbulence in the barrier layer can be minimized as far as possible during the production process of the sample container in order to subsequently form an advantageous continuous and closed barrier layer.

[0037] Also advantageous is an embodiment according to which it can be provided that the second side surface of the first groove and the first side surface of the first groove are formed within a second wall thickness section of the container wall, which second wall thickness section extends radially from the outer surface towards the inner surface of the sample container relative to the longitudinal axis, wherein the second wall thickness section has a wall thickness that originates from a wall thickness range whose lower limit is 25% of the total wall thickness of the sample container and whose upper limit is 60% of the total wall thickness of the sample container, wherein the wall thickness of the second wall thickness section is in particular 33% of the total wall thickness of the sample container. Since the constriction by the first groove on the outer circumference of the sample container is thus limited relative to the total wall thickness, the continuous and closed formation of the barrier layer is promoted.

[0038] Furthermore, it can be provided that a plurality of support elements are provided distributed over the circumference, which support elements are arranged on the outer surface of the second container wall section of the container wall and project beyond the outer surface on the side facing away from the longitudinal axis, wherein the support elements are predominantly formed from the first plastic material. The provision of support elements thus creates a better positional fixation in the joined position between the sample container and the extension element. This prevents kinking and thus unintentional detachment of the extension element from the sample container when the coupling elements are coupled.

[0039] Furthermore, it may be advantageous for the support elements to be designed as webs, which webs have a parallel longitudinal extension with respect to the longitudinal axis. This achieves even better guidance and axial stabilization of the sample container and the extension element relative to each other.

[0040] Furthermore, it can be provided that an outer envelope of the webs forming the support elements has a diameter that is equal to or slightly larger than an inner diameter of the side wall of the extension element in the region of its open end. This achieves a sufficient supporting effect and additional mutual axial stabilization in the joined position. This further increases the flexural rigidity of the tubular components joined to form the removal assembly.

[0041] Also advantageous is a form of embodiment according to which it can be provided that in the bottom wall of the extension element at least one opening, preferably several openings

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breaks, is or are formed, which break or breaks penetrate or penetrate the base wall. This prevents the build-up of a pressure difference with respect to the ambient pressure (overpressure, underpressure) within the interior space defined by the extension element, despite the design of the coupling device. Furthermore, it also evacuates the collection space during a subsequent evacuation process. This also prevents any possible forced pressing and associated suction of the air present in the interior of the extension element into the collection space of the sample container. This also extends the storage life of the sampling assembly until it is used.

[0042] According to a further development, it is possible for the at least one opening to be arranged radially spaced from the longitudinal axis, and for the bottom wall to be continuous in the region of the longitudinal axis. This creates a stable support surface in the center of the bottom wall, which is continuous and uninterrupted. Furthermore, a central injection point can be selected and maintained for the manufacturing process.

[0043] Furthermore, it may be expedient if the at least one first coupling element is arranged predominantly in the second container wall section. This creates a flat transition between the extension element and the sample container in the outer peripheral region. Furthermore, this also allows for a simple molding of the sample container and extension element. Since both the extension element and the sample container can have an outer surface made of the first plastic material, the surface properties of the two components are the same, which simplifies handling of the removal assembly.

[0044] Furthermore, it can be provided that the at least one second coupling element is formed by a wall section of the side wall of the extension element and by a second groove in the inner surface of the side wall of the extension element, which extends over the circumference. This allows the joining process to be carried out easily with a prior mutual axial alignment. Furthermore, the constriction by the first groove in the outer surface of the sample container can be formed within the boundaries of the second wall thickness section, since a mutually acting coupling device is formed between the extension element and the sample container. This enables an undisturbed formation of the barrier layer in the coupling region and especially in the region of the first container wall section.

[0045] According to a particular embodiment, it is possible for the wall section of the side wall of the extension element to engage in the first groove when the first and second coupling elements are in coupling engagement, and for a second side surface of the first groove, closer to the bottom of the sample container, and a wall section of the container wall of the sample container adjoining it in the direction of the bottom of the sample container to engage in the second groove. Thus, the coupling device with the cooperating coupling elements can be formed with minimal material expenditure by arranging and forming only recesses or grooves and only wall sections of the side wall and wall sections of the container wall. This eliminates the need for additional connecting means in the coupling area, such as a welded joint, an adhesive joint, or another material connection. Furthermore, the constriction by the first groove in the outer surface of the sample container can be formed within the limits of the second wall thickness section, since a mutually acting coupling device is formed between the extension element and the sample container. This allows for an undisturbed formation of the barrier layer in the coupling area and especially in the area of the first container wall section.

[0046] According to an advantageous development, it can be provided that a closure device is provided, by means of which closure device the first open end of the sample container is closed. This allows, even before the collection space is filled,

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A sterile collection room must be provided until use.

[0047] In particular, it may be advantageous if the collection chamber closed by the closure device is lowered to a pressure lower than the ambient pressure. This facilitates the filling and suction of the sample into the collection chamber, and the filling volume of the sample quantity can be more precisely determined in advance.

[0048] Furthermore, it can be provided that, viewed in axial section, the outer surface and the inner surface of the first container wall section each merge directly into the outer surface and the inner surface of the second container wall section, forming a transition curve, wherein the transition curve has a radius that originates from a radius range whose lower limit is 0.3 mm, in particular 0.5 mm, and whose upper limit is 80 mm, in particular 50 mm. This allows a sufficiently high fill level to be achieved in the bottom region of the sample container even with a small fill volume. This makes it easier to control the fill volume and, moreover, facilitates sample removal even with a small sample volume. This also allows the residual volume or dead volume of the sample in the bottom region of the sample container to be kept very low. Furthermore, the formation of the barrier layer is promoted by selecting the transition radius within the specified value range. In particular, in conjunction with the constriction by the first groove on the outer surface of the sample container, the formation of the barrier layer starting from the first container wall section in the direction of the first open end of the sample container can be advantageously influenced, so that a continuous and uninterrupted barrier layer is formed.

[0049] For a better understanding of the invention, it is explained in more detail with reference to the following figures.

[0050] They show in a highly simplified, schematic representation:

[0051] Fig. 1 shows a removal assembly with sample container, extension element and closure device arranged at a distance therefrom, in a diagrammatic representation, partially in section;

[0052] Fig. 2 shows the sample container according to Fig. 1 in axial section; [0053] Fig. 3 shows the extension element according to Fig. 1 in axial section;

[0054] Fig. 4 shows the coupling device between the sample container and the extension element with the coupling elements in engagement, in axial section and enlarged view;

[0055] Fig. 5 is a view of the bottom wall of the extension element.

[0056] By way of introduction, it should be noted that in the variously described embodiments, identical parts are provided with identical reference numerals or identical component designations, whereby the disclosures contained in the entire description can be applied mutatis mutandis to identical parts with identical reference numerals or identical component designations. Furthermore, the positional information chosen in the description, such as top, bottom, side, etc., refers to the directly described and illustrated figure, and these positional information must be applied mutatis mutandis to the new position in the event of a change in position.

[0057] Figs. 1 to 5 show a collection assembly 1 comprising several components, which serves for receiving and collecting small amounts of body fluids, in particular blood samples, urine, saliva, or the like. Typically, so-called sample collection tubes, which can also be referred to as blood collection tubes or blood collection tubes, are used for such purposes. Even though these collection tubes are usually referred to as blood collection tubes or blood collection tubes, other previously mentioned body fluids or other biological fluid samples can also be received and collected therein.

[0058] In order to perform automated sample analysis and/or

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To enable centrifugation, such collection tubes have predefined and standardized dimensions. Standard dimensions include, for example, the outer nominal diameter and the nominal axial length. Tubes are available with a nominal diameter of 13 mm or 16 mm. The nominal axial length can be, for example, 75 mm or 100 mm. The abbreviation for a sealed tube with a 13 mm nominal diameter and an axial length of 75 mm can be, for example, 13/75. Dimensions with nominal diameters or nominal axial lengths that differ from those specified above can also be used.

[0059] Since this collection assembly 1 is designed for a smaller receiving volume than the previously mentioned collection tubes, the receiving space should also have a smaller receiving volume than the standard tubes. For this purpose, a wide variety of designs are proposed to reduce the receiving volume while maintaining approximately the same external standard dimensions. There are embodiments as a one-piece solution or as a multi-piece or multi-element solution.

[0060] The collection assembly 1 is preferably used for the collection of blood, particularly venous blood, which is collected in small quantities and stored for subsequent examinations in the respective collection assembly 1. However, other biological samples can also be collected in the collection chamber. The collection chamber 14 can also be referred to as a receiving chamber, which has a smaller collection volume compared to the collection tubes having a standardized size.

[0061] For example, the collection chamber 14 of the sample container 2 can have a holding volume with a lower limit of 1 ml and an upper limit of 3 ml, in particular between 1.5 ml and 2.5 ml (milliliters). Thus, the collection chamber 14 has a reduced holding volume compared to the collection containers described above, which have standard dimensions. A sample tube with the standard dimension 13/75, for example, can have a maximum holding volume of 4.5 ml. Attempts have already been made to hold only 1 ml of sample in those sample tubes with the standard dimension 13/75 and the holding volume of 4.5 ml. Due to the large volume difference between the maximum possible holding volume of 4.5 ml and the small fill volume of 1 ml, the extent of the pressure difference is very sensitive for sample tubes with a pressure in the holding chamber that is lower than the ambient pressure. The preset, small pressure difference of 1 ml used to determine the intake volume can vary within certain limits under changing ambient conditions, such as temperature and air pressure, and can lead to a different intake volume during sampling. Due to the reduced maximum intake volume of the intake chamber or collection chamber in this sampling assembly 1, the pressure difference relative to the ambient pressure can also be increased in the evacuated version.

[0062] Due to advances in technology, an ever-smaller sample quantity is required for the determination of clinical parameters. The sample quantity can also be referred to as the sample volume. Previous collection or sample tubes for small sample volumes, however, had smaller dimensions, particularly length dimensions, compared to the standardized dimensions. However, in order to be able to insert and accommodate this collection assembly 1 into the likewise standardized centrifugation devices or laboratory automation systems, the designs described below are designed in such a way that, despite the smaller capacity, use in standardized centrifuges, laboratory automation systems, analytical devices, or the like is possible.

[0063] The removal assembly 1 comprises at least one sample container 2 and an extension element 3 that can be joined thereto. Figure 1 shows the joined and assembled position of the two components, with a closure device 4 additionally being shown, but in a position lifted off from it. Figures 2 and 3 show the respective component, namely the sample container 2 and the extension element 3, on its own.

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presents.

[0064] The sample container 2 in turn comprises a container wall 5 with a first container wall section 6 and a second container wall section 7 arranged adjoining it. The container wall 5 extends between a first open end 8 and a second end 9 arranged at a distance therefrom and is delimited by an outer surface 10 and an inner surface 11. Furthermore, the container wall 5 also defines a longitudinal axis 12. The same designation of the longitudinal axis is also chosen for the extension element 3, since in the assembled, joined position of the sample container 2 with the extension element 3, the common longitudinal axis 12 is formed and both longitudinal axes 12 are arranged congruently with one another.

[0065] In the area of the second end 9, a base 13 is provided, which is integrally connected to the container wall 5 and forms a tight seal. The container wall 5 and the base 13 together define a collecting space 14.

[0066] Preferably, both the sample container 2 and the extension element 3 are each manufactured separately from a plastic material in an injection molding process. The extension element 3 can be predominantly transparent to crystal-clear and can be made of a first plastic material selected from the group consisting of PP (polypropylene), PS (polystyrene), PET (polyethylene terephthalate), PE (polyethylene), HD-PE (high-density polyethylene), PA (polyamide), PC (polycarbonate), or a polymer with similar technical properties. The sample container 2 is formed from a first layer 38 made of the first plastic material and a second layer 39 made of a second plastic material. The second plastic material can be selected from a group comprising the plastics EVA (ethylene-vinyl acetate) or EVOH, PP (polypropylene), polyolefin, cycloolephine copolymer, or cycloolephine polymer, or a polymer with equivalent technical properties. The second layer 39 is thus designed as a barrier layer.

[0067] In this sense, a barrier layer is understood to mean a wall of the sample container 2 designed in such a way that it has advantageous properties with regard to inhibiting the diffusion of certain substances through the second layer or through the interaction of the second layer with another layer. It is conceivable that a liquid additive with a water content is present in the collection space 14 of the sample container 2 even before a sample is taken and even during storage of the previously unused sample container 2. Thus, the second layer 39 made of the second plastic material can, among other things, in combination with the first layer 38 or on its own, have a diffusion-inhibiting effect on oxygen and similar gaseous molecules. At the same time, the combination of the first layer 38 and the second layer 39 can have a diffusion-inhibiting effect on water and similar molecules, since the first plastic material in particular has hydrophobic properties. The diffusion-inhibiting properties of the barrier layer, or here the second layer 39, also in conjunction with the first layer 38, thus provide improved protection against environmental influences and against degradation of the contents of the sample container 2. Among other advantages, this extends the storage time and the shelf life of the contents of the sample container 2 in the collection chamber 14.

[0068] In the illustrated embodiment of the collection assembly 1, the barrier layer made of the second plastic material, or the second layer 39, is completely enclosed by the first plastic material over its entire surface, or is embedded or encapsulated therein. Thus, the first layer 38 is understood to mean that the first layer 38 completely encloses the second layer 39, so that the second layer 39 does not come into contact with a sample or other contents in the collection space 14 of the sample container 2, nor with the surroundings of the sample container 2.

[0069] For demolding the components from the injection mold, a slight draft is usually provided to facilitate the demolding process. Thus, the container wall 5 has a slight conicity, starting from the area of the open end 8 in the direction of the second end 9. In principle, both the sample container 2 and

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the extension element 3 has a circular cross-section and is thus tubular.

[0070] The sample container 2 can be manufactured using a multi-component injection molding process or a co-injection process, wherein the common injection point for the first and second plastic materials can preferably be selected in the region of the base 13. Thus, the second layer 39 can be molded onto the first layer 38 and vice versa, thereby creating a stable material bond. At the open end of the sample container 2 in the region of the first open end 8, the second layer 39 can be enclosed by the first layer 38 such that the first layer 38 has a layer thickness of at least 0.3 mm starting from the front end. Thus, on the one hand, the barrier layer is completely encapsulated and, on the other hand, the barrier layer or the second layer 39 is formed as close as possible to the open end of the sample container 2. Thus, with appropriate coverage by means of the closure device 4, the diffusion-inhibiting properties of the sample container 2 are improved.

[0071] In this embodiment of the sample container 2, it is provided that the first container wall section 6 is basically hollow-cylindrical and has a first diameter dimension 15. Due to the previously described draft angle, the diameter dimension 15 can be designed to decrease slightly from the first open end 8 toward the bottom 13. However, a constant diameter dimension 15 could also be provided.

[0072] The second container wall section 7 of the container wall 5 is here hollow conical in shape and has, at least in sections, a smaller second diameter dimension 16. The term "section-wise" is used because, viewed in axial section, the outer surface 10 of the first container wall section 6 only merges into the outer surface 10 of the second container wall section 7 by forming a kink, an angled portion, or a transitional rounding, and has the same diameter in this transition region.

[0073] It is also possible for the inner surface 11 of the first container wall section 6 to merge into the inner surface 11 of the second container wall section 7, forming a further, internal transition curve 44 or a further bend or kink. Due to the hollow conical shape, a sufficient fill level can be achieved in the collection chamber 14 even with a small fill quantity, which is sufficient for the proper determination of the fill volume and the subsequent sampling. Furthermore, the manufacturing process, in particular the injection point in the bottom end 9 of the base 13, can be selected in the center thereof.

[0074] The transition curve 44 on the inner diameter of the sample container 2 in the region of the transition section 28 is designed with a view to an advantageous material flow of the first and second plastic materials during the manufacturing process. Since a coupling device 25 with a first groove 30 is formed in this region, the existing constriction can cause a disruption or inadequate formation of the barrier layer during the manufacturing process of the sample container 2. Accordingly, depending on the embodiment of the sample container 2, according to the layer thicknesses of the first and second layers 38, 39 and the layer thickness ratios, a transition curve 44 in the range between 0.5 mm and 50 mm is considered particularly advantageous. In particular, the selection of the transition curve 44 when selecting the injection point in the area of the bottom 13 has an effect on the propagation of the barrier layer or the second layer 39 from the transition section 28 in the direction of the first open end 8 of the sample container 2. In order to be able to produce a continuously intact barrier layer, a corresponding transition curve 44 must be carefully selected.

[0075] Furthermore, at least one support element 17, but preferably several support elements 17, can be provided, which is or are arranged on the outer surface 10 of the second container wall section 7 of the container wall 5 and protrudes beyond the outer surface 10 on the side facing away from the longitudinal axis 12. If several support elements 17 are provided-

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These can be distributed, in particular evenly distributed, around the circumference. To achieve a good supporting effect for the extension element 3, at least three to four of them must be arranged or provided.

[0076] The support element(s) 17 can be designed as webs and have an approximately to completely parallel longitudinal extension with respect to the longitudinal axis. The longitudinal extension refers to the longitudinal course of the webs, which can also be provided with a conventional draft angle for easier demolding from the injection mold. A radial arrangement can also be provided. The support elements 17 serve for the axial alignment and mutual stabilization of the sample container 2 and the extension element 3 in the joined position. In addition, they can also be used for mutual support and connection if a dimensional coordination has been achieved. The mutual support and connection is to be achieved by means of the aforementioned coupling device 25 in the transition section 28, which coupling device 25 will be described in more detail below. The coupling device 25 could also be referred to as a coupling device.

[0077] It would also be conceivable for the sample container 2 to be hollow-conical in its second container wall section 7 of the container wall 5, and for the coupling device 25 not to be provided. In this case, the mutual support and connection of the sample container 2 and the extension element 3 could be achieved by a fixed connection of at least one of the support elements 17 to the extension element 3. This could be achieved by means of an adhesive process or a welding process. This will be explained in more detail below.

[0078] The extension element 3, in turn, comprises a side wall 18, which extends between a first open end 19 and a second end 20. A bottom wall 21 is arranged or formed adjacent to the second end 20. The side wall 18 is bounded by an outer surface 22 and an inner surface 23 and also has a preferably circular cross-section. The bottom wall 21 of the extension element 3 can be dome-shaped, in particular a hollow spherical dome-shaped.

[0079] At least one opening 24 can be formed in the bottom wall 21 of the extension element 3, which completely penetrates or passes through the bottom wall 21. This can be seen from a synopsis of Figs. 1, 3, and 5. Preferably, however, several openings 24 can be provided, four in the present exemplary embodiment. The opening(s) 24 are further arranged at a distance from the longitudinal axis 12 in the radial direction. Thus, the bottom wall 21 remains continuous and closed in a central region or a central section around the longitudinal axis 12. In this way, a good and unhindered introduction of force, such as occurs during support during a centrifugation process, can be achieved in this surface section of the bottom wall 21. Furthermore, a central injection point can also be selected for production. Thus, despite the arrangement and design of the openings 24, the stability of the bottom wall 21 can be maintained almost unchanged. The opening(s) 24 also serve to enable access to the interior of the extension element 3, even when the sample container 2 and the extension element 3 are joined together to form a single unit. This is particularly true when the first open end 19 of the extension element 3 is engaged with the sample container 2 by means of the coupling device 25, and the coupling device 25 forms an airtight connection.

[0080] The coupling connection can be designed to be predominantly airtight. The openings 24 can prevent unwanted air from being trapped in the interior of the extension element 3. If the interior is completely sealed, this can lead to an increase in internal pressure when the temperature rises and, subsequently, to an unwanted separation of the sample container 2 and the extension element 3. Furthermore, even when the collection chamber 14 is evacuated, air present in the interior of the extension element 3 can be forced or sucked into the collection chamber 14.

[0081] The extension element 3 serves, together with the sample container 2, to form a

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to be joined into a related structural unit, namely the removal assembly 1. By separately forming the sample container 2 and the extension element 3, the manufacturing process can be optimized for each of the components, and despite the smaller absorption quantity or the smaller absorption volume, the usual standard dimensions in length and diameter can be achieved with good supporting effect and strength. Separate manufacturing can also have the advantage that the overall lengths of each component, i.e., the sample container 2 and the extension element 3, can be more easily varied and coordinated with one another. If a shorter sample container 2 is required, the extension element 3 must be extended by the shortened length of the sample container 2.

[0082] In order to connect the sample container 2 to the extension element 3 to form a coherent structural unit and also to hold it firmly and fixedly thereto, a dedicated coupling device 25 is provided, which comprises at least one first coupling element 26 and at least one second coupling element 27 that can be coupled thereto. The at least one first coupling element 26 is arranged or formed on the sample container 2, and the at least one second coupling element 27 is arranged or formed on the extension element 3. When the coupling elements 26, 27 are in coupling engagement with one another, the removal assembly 1 is formed in its tubular shape. The coupling engagement takes place on a positive basis between the two interlocking coupling elements 26 and 27. These can also be referred to as coupling elements. The coupling engagement preferably takes place in such a way that separation of the two components from one another can only be carried out with considerable force. This prevents unintentional separation of the two components from one another. The coupling device can be designed in the form of a snap connection.

[0083] In the coupling position, the sample container 2 projects with its second container wall section 7, which is spaced from the open end 8 in the direction of the longitudinal axis 12, at least partially into the first open end 19 of the extension element 3.

[0084] The at least one first coupling element 26 is arranged or formed in a transition section 28 between the first container wall section 6 and the second container wall section 7. The transition section 28 is located in the region of the previously described bend between the outer surfaces 10 of the container wall 5, which extend at an angle to one another. Preferably, the at least one first coupling element 26 is arranged with a predominant portion, in particular a surface portion, in the second container wall section 7 and can also extend slightly into the first container wall section 6.

[0085] It would also be possible to displace the first coupling element 26 of the coupling device 25 further in the direction of the first open end 8 and thus to arrange it within the first container wall section 6. In order to create a flat transition between the outer surface 22 of the extension element 3 and the outer surface 10 of the sample container 2, the wall thicknesses must be dimensionally matched to one another.

[0086] The at least one first coupling element 26 can be formed, for example, by at least one first recess arranged in the outer surface 10 of the container wall 5 and a wall section 29 of the container wall 5 of the sample container 2 adjoining it in the direction of the bottom 13 of the sample container 2. Instead of the recess or recesses, however, a first groove 30 can also be provided, which is designed to be continuous over the circumference of the sample container 2. The wall section 29 also forms part of the first coupling element 26. In order to form an axial stop for the extension element 3, in particular an end face 31 of the side wall 18 in the region of the open end 19, a first side surface 32 of the first recess or the first groove 30 is provided. The side surface 32 of the first recess or the first groove 30 forms a stop surface.

[0087] As can be seen from the illustration in Fig. 3, the side wall 18 of the extension element 3 is formed as a hollow cylinder between the first open end 19 and the second end 21. As already described above, the side wall 18 can also be formed or provided with a slight draft angle in the region of the outer surface 22 and/or in the region of the inner surface 23. This also falls under the term "hollow cylinder-

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der-shaped". Except for the provision and formation of the second coupling element 27, the side wall is continuous and rectilinear in axial section between the first open end 19 and the second end 21.

[0088] The at least one second coupling element 27 is formed here by a wall section 33 of the side wall 18 of the extension element 3 in the immediate region of the first open end 19 and by at least one second recess arranged in a recessed manner in the inner surface 23 of the side wall 18. Instead of the recess or recesses, however, a second groove 34 can also be provided, which is recessed continuously in the inner surface 23, as seen over the circumference of the sample container 2. The wall section 33 of the side wall 18 of the extension element 3 also forms part of the second coupling element 27 here.

[0089] If the coupling elements 26 and 27 are in coupling engagement with one another, the wall section 33 of the side wall 18 of the extension element 3 engages in the first recess or in the first groove 30 of the sample container 2. Furthermore, a second side surface 35 of the first recess or the first groove 30, which is closer to the bottom 13 of the sample container 2, and the wall section 29 of the container wall 5 of the sample container 2 adjoining it in the direction of the bottom 13 of the sample container 2, engages in the second recess or in the second groove 34 of the extension element 3. The wall section 29 is formed directly by a partial section of the hollow conical second container wall section 7 of the container wall 5.

[0090] Due to the constriction in the outer surface or the first groove 30 of the sample container 2, the manufacturability of the sample container 2 by means of co-injection processes or multi-component injection molding processes is made more difficult, since a continuous barrier layer must also be formed in the region of the first groove 30. As already described above, this difficulty in manufacturability is addressed, on the one hand, by means of the transition curve 44. On the other hand, as in the illustrated embodiment of the sample container 2, the wall of the sample container can be divided into several wall sections, wherein the barrier layer or the second layer 39 can be formed within a first wall thickness section 42 of the container wall 5. The first wall thickness section 42 extends from the inner surface 11 in the radial direction relative to the longitudinal axis 12 outwards or in the direction of the outer surface 10. The first wall thickness section 42 can have a thickness of 25% to 80% of the total wall thickness of the sample container 2 and in particular a thickness in the radial direction of 40% of the sample container 2 of the sample container. Thus, it can be achieved that the barrier layer in the region of the first groove 30, with appropriate layer thickness dimensioning, as already described above, has a constriction in the sense of a reduced layer thickness, but further that the barrier layer is in any case continuous, wherein the layer thickness in the region of the transition section 28 has a lower limit of at least 0.01 mm, in particular 0.025 mm, and an upper limit of 0.5 mm, in particular 0.01 mm. In each case, a first surface 40 of the second layer 39 and a second surface 41 of the second layer 39 are completely covered by the first layer 38 or by the first plastic material.

[0091] An embodiment is also conceivable in which the barrier layer is formed in a second wall thickness section 43. The second wall thickness section 43 extends from the outer surface 10 in the radial direction relative to the longitudinal axis 12 inwards, or in the direction of the inner surface 11. The second wall thickness section 43 can have a thickness of 25% to 60% based on the total wall thickness of the sample container 2. With this possible embodiment, in which the barrier layer is formed in a second wall thickness section 43, the purpose can be that the barrier layer is advantageously formed in the casting direction, starting from the first groove 30 in the direction of the first open end 8.

[0092] As already briefly described above, the support elements 17 can be arranged or formed on the second container wall section 7 of the container wall 5. By selecting the hollow conical design of the second container wall section 7, a sufficient distance

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support of the extension element 3 on the sample container 2. Therefore, the support elements 17 are provided for guidance and positional stabilization in the coupled position, in particular also for absorbing transverse forces. For example, it is also provided here that an outer envelope of the support elements 17, in particular of the webs, has a diameter 36 that is equal to or slightly larger than an inner diameter 37 of the side wall 18 of the extension element 3 in the region of its open end 19. With a slight oversize of the support elements 17 designed as webs in the region of their outer envelopes, in addition to the coupling connection, a press fit can also be achieved in the joined state by means of a press fit and, associated with this, a snug contact and support of the inner surface 23 of the extension element 3 on the support elements 17, in particular the webs. This allows for further mutual stabilization of the sample container 2 and the extension element 3 in addition to the coupling connection.

[0093] In addition, it would also be possible to form an adhesive bond and/or a welded connection in at least one mutual contact area of a support element 17, in particular one of the webs, and the inner surface 23 of the extension element 3. This can be done, for example, on a material-to-material basis. The welding process can be carried out, for example, by means of ultrasonic welding or the like.

[0094] However, it would also be possible to form the outer envelope of the support elements 17, in particular the webs, with a diameter slightly smaller than the inner diameter 37 of the side wall 18 of the extension element 3 in the region of its open end 19. However, this would result in less effective mutual stabilization and axial alignment. In the event of buckling stress in the coupling area, this could lead to an undesired separation of the sample container 2 and the extension element 3.

[0095] This makes it possible to form the outer envelope of the support elements 17, in particular of the webs, with a diameter which is slightly smaller than or equal to or even slightly larger than the inner diameter 37 of the side wall 18 of the extension element 3 in the region of its open end 19.

[0096] The closure device 4 shown in Fig. 1 serves, in a known manner, to close the first open end 8 of the sample container 2 and thus also the collection chamber 14 from the external environment. The closure is to be designed to be at least liquid-tight, and in particular also gas-tight, as has been done in a known manner with standard tubes. In addition, the collection chamber 14 can also be lowered to a pressure that is reduced relative to the ambient pressure. Due to the small absorption volume compared to standardized collection tubes, the pressure in the collection chamber 14 in this sample container 2 can thus be further reduced in order to better predetermine the suction volume, although this is not absolutely necessary.

[0097] There may be applications in which the collection chamber 14 is closed with the closure device 4, but in order to introduce the sample, the entire closure device 4 must be removed from the open end 8 of the sample container 2, and only then can the corresponding sample be filled in. It would also be possible for the inner surface 11 and, if appropriate, also the bottom 13 with its bottom surface facing the collection chamber 14 to be provided with a coating for treating the filled sample.

[0098] The closure device 4 is shown in Fig. 1. Reference is made to the various designs, as described, inter alia, in EP 0 419 490 B1, EP 0 445 707 B1, or EP 1 711 412 B1. To avoid unnecessary repetition, reference is made to these patents and their respective family members for the possible designs of the closure device 4.

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LIST OF REFERENCE SYMBOLS

1 Removal assembly 29 Wall section 2 Sample container 30 First groove 3 Extension element 31 End face 4 Closure device 32 First side surface 5 Container wall 33 Wall section 6 First container wall section 34 Second groove 7 Second container wall section 35 Second side surface 8 First open end 36 Diameter 9 Second end 37 Inner diameter 10 Outer surface 38 First layer 11 Inner surface 39 Second layer 12 Longitudinal axis 40 First surface of the second layer 13 Bottom layer 14 Collection space 41 Second surface of the second layer 15 First diameter dimension 42 First wall thickness section 16 Second diameter dimension of the container wall 43 Second wall thickness section 17 Support element of the container wall 18 Side wall 44 Transition curve

19 first open end 20 second end

21 Floor wall

22 exterior surface

23 inner surface

24 Breakthrough

25 coupling device 26 first coupling element 27 second coupling element

28 Transition section

16 / 23

Claims (23)

A 'hes AT 525 932 B1 2025-10-15 Ss N patent claims 1. Collection assembly (1) for receiving a small amount of a body fluid, in particular a blood sample, urine, saliva, comprising - a sample container (2) with a container wall (5), which container wall (5) extends from a first open end (8) to a second end (9), is delimited by an outer surface (10) and an inner surface (11) and defines a longitudinal axis (12), and with a base (13), which base (13) closes the second end (9) of the container wall (5) and, together with the container wall (5), defines a collection space (14), and wherein - the container wall (5) comprises, in the direction of the longitudinal axis (12), a first container wall section (6) and an adjoining second container wall section (7), wherein - the first container wall section (6) is hollow-cylindrical with a first outer diameter dimension (15) and is arranged starting from the open end (8), wherein - the second container wall section (7) has, at least in sections, a smaller second diameter dimension (16) with respect to the first outer diameter dimension (15) of the first container wall section (6), and wherein - a transition section (28) is arranged between the first container wall section (6) and the second container wall section (7), - an extension element (3) with a side wall (18), which side wall (18) extends from a first open end (19) to a second end (20), and with a bottom wall (21) arranged adjacent to the second end (20), wherein the bottom wall (21) of the extension element (3) is dome-shaped, in particular hollow spherical dome-shaped, and wherein - the sample container (2) with its second container wall section (7) arranged at a distance from the first open end (8) in the direction of the longitudinal axis (12) projects at least partially into the first open end (19) of the extension element (3), - a coupling device (25) with at least one first coupling element (26) and with at least one second coupling element (27), wherein - the at least one first coupling element (26) is arranged or formed on the sample container (2) and the at least one second coupling element (27) is arranged or formed on the extension element (3), and wherein - when the first and second coupling elements (26, 27) are in coupling engagement, the extension element (3) is positively coupled to the sample container (2) to the removal assembly (1) by means of a snap connection formed by the coupling elements (26, 27), - wherein the second container wall section (7) of the container wall (5) of the sample container (2) is hollow conical, - wherein the at least one first coupling element (26) is arranged in the transition section (28) between the first container wall section (6) and the second container wall section (7) of the container wall (5), - wherein the side wall (18) of the extension element (3) is formed as a hollow cylinder between the first open end (19) and the second end (21), - wherein the side wall (18) is continuous and straight in axial section between the first open end (19) and the second end (21), - wherein the sample container (2) has a first layer (38) made of a first plastic material selected from the group PE, HD-PE, PET or PP, and - wherein the sample container (2) has at least one second layer (39) made of a second plastic material selected from the group comprising ethylene-vinyl acetate or EVOH, PP, polyolefin, cycloolephine copolymer, or cycloolephine polymer, characterized in that - the second layer (39) is a barrier layer and has a first layer thickness with a range whose lower limit is 0.01 mm, in particular 0.05 mm, and whose upper limit is 0.9 mm, in particular 0.2 mm, wherein - the second layer (39) of the sample container (2) in the region of the transition section (28) has a second layer thickness with a range whose lower limit is 0.01 mm, in particular 0.025 mm, and whose upper limit is 0.5 mm, in particular 0.1 mm, - the second layer (39) in the region of the transition section (28) is covered over its entire surface on a second surface (41) facing away from the first coupling element (26) by the first layer (38) or a further layer, and wherein - the container wall (5) of the sample container (2) is designed as a multi-barrier layered body, wherein the second layer (39) is formed continuously and coherently within the container wall (5) of the sample container (2), wherein the second layer (39) is completely encased by the first layer (38) or the second layer (39) is embedded in the first layer (38) and is formed directly connected to the first layer (38) or is formed thereon. 2. Removal assembly (1) according to claim 1, characterized in that the second layer (39) in the region of the transition section (28) is covered over its entire surface on a first surface (40) facing the first coupling element (26) by the first layer (38) or a further layer. 3. Removal assembly (1) according to one of the preceding claims, characterized in that the sample container (2) has an average total wall thickness with a wall thickness range whose lower limit is 0.5 mm, in particular 0.9 mm, and whose upper limit is 1.5 mm, in particular 1.1 mm. 4. Removal assembly (1) according to one of the preceding claims, characterized in that the container wall (5) is produced from the first layer (38) and the at least one second layer (39) in a two-component co-injection process. 5. Removal assembly (1) according to one of claims 2 to 4, characterized in that the second layer (39) is formed within a first wall thickness section (42) of the container wall (5), which first wall thickness section (42) is closest to the longitudinal axis (12) in the radial direction with respect to the container wall (5) or is the inner section of the container wall (5) with respect to the collecting space (14). 6. Removal assembly (1) according to claim 5, characterized in that the first wall thickness section (42) extends from the inner surface (11) of the sample container (2) radially to the longitudinal axis (12) in the direction of the outer surface (10), wherein the first wall thickness section (42) has a wall thickness from a range whose lower limit is 25% of the total wall thickness of the sample container (2) and whose upper limit is 80% of the total wall thickness of the sample container (2), wherein the wall thickness of the first wall thickness section (42) is in particular 40% of the total wall thickness of the sample container (2). 7. Removal assembly (1) according to one of claims 2 to 6, characterized in that the second layer (39) is formed in a circumferentially closed manner in the region of the bottom (13) of the sample container (2), wherein the first layer (38) completely seals the collection space (14) from the second layer (39) and wherein the first layer (38) completely seals the surroundings of the sample container (2) from the second layer (39). 8. Removal assembly (1) according to one of the preceding claims, characterized in that in the region of the first open end (8) of the sample container (2) the second layer (39) is completely encased by the first layer (38), wherein in the region of an end face (31) of the first open end (8) of the sample container (2) the first layer (38) has a layer thickness of at least 0.3 mm. 18 / 23 10. 11. 12. 13. 14. 15. 16. 17. AT 525 932 B1 2025-10-15 Removal assembly (1) according to one of the preceding claims, characterized in that the at least one first coupling element (26) is designed as a first groove (30) running around the circumference and the wall section (29) of the side wall of the sample container (2) adjoining it in the direction of the bottom (13) of the sample container (2). Removal assembly (1) according to one of the preceding claims, characterized in that a first side surface (32) of the first groove (30) facing the open end (8) of the sample container (2) forms a stop surface for an end face (31) of the extension element (3) in the region of its first open end (19), and the first side surface (32) forms an axial stop for the first end face (31) of the extension element (3). Removal assembly (1) according to one of the preceding claims, characterized in that a second side surface (35) of the first groove (30) facing away from the open end (8) of the sample container (2) forms a stop surface for a second groove (34) of the extension element (3) in the region of its first open end (19), and the second side surface (35) forms an axial stop for the second groove (34) of the extension element (3). Removal assembly (1) according to claim 10 or 11, characterized in that the second side surface (35) of the first groove (30) and the first side surface (32) of the first groove (30) are formed within a second wall thickness section (43) of the container wall (5), which second wall thickness section (43) extends radially from the outer surface (10) in the direction of the inner surface (11) of the sample container (2) relative to the longitudinal axis (12), wherein the second wall thickness section (43) has a wall thickness which originates from a wall thickness range whose lower limit is 25% of the total wall thickness of the sample container (2) and whose upper limit is 60% of the total wall thickness of the sample container (2), wherein the wall thickness of the second wall thickness section (43) is in particular 33% of the total wall thickness of the sample container (2). Removal assembly (1) according to one of the preceding claims, characterized in that a plurality of support elements (17) distributed over the circumference are provided, which support elements (17) are arranged on the outer surface (10) of the second container wall section (7) of the container wall (5) and project beyond the outer surface (10) on the side facing away from the longitudinal axis (12), wherein the support elements (17) are formed predominantly from the first plastic material. Removal assembly (1) according to claim 13, characterized in that the support elements (17) are designed as webs, which webs have a parallel longitudinal extension with respect to the longitudinal axis (12). Removal assembly (1) according to claim 13, characterized in that an outer envelope of the webs forming the support elements (17) has a diameter (36), which diameter (36) is equal to or slightly larger than an inner diameter (37) of the side wall (18) of the extension element (3) in the region of its open end (19). Removal assembly (1) according to one of the preceding claims, characterized in that at least one opening (24), preferably a plurality of openings, is or are formed in the bottom wall (21) of the extension element (3), which opening (24) or openings pass through or pass through the bottom wall (21). Removal assembly (1) according to claim 16, characterized in that, according to A before, the at least one opening (24) is arranged at a distance from the longitudinal axis (12) in the radial direction and the bottom wall (21) is formed continuously in the region of the longitudinal axis (12). It's AT 525 932 B1 2025-10-15 Ss N 18. Removal assembly (1) according to one of the preceding claims, characterized in that the at least one first coupling element (26) is arranged with a predominant portion in the second container wall section (7). 19. Removal assembly (1) according to one of the preceding claims, characterized in that the at least one second coupling element (27) is formed by a wall section (33) of the side wall (18) of the extension element (3) and by a second groove (34) running over the circumference in the inner surface (23) of the side wall (18). 20. Removal assembly (1) according to one of the preceding claims, characterized in that when the first and second coupling elements (26, 27) are in coupling engagement, the wall section (33) of the side wall (18) of the extension element (3) engages in the first groove (30) and that a second side surface (35) of the first groove (30) closer to the bottom (13) of the sample container (2) and a wall section (29) of the container wall (5) of the sample container (2) adjoining it in the direction of the bottom (13) of the sample container (2) engage in the second groove (34). 21. Removal assembly (1) according to one of the preceding claims, characterized in that a closure device (4) is provided, by means of which closure device (4) the first open end (8) of the sample container (2) is closed. 22. Removal assembly (1) according to claim 21, characterized in that the collecting space (14) closed by the closure device (4) is lowered to a pressure reduced relative to the ambient pressure. 23. Removal assembly (1) according to one of the preceding claims, characterized in that, viewed in axial section, the outer surface (10) and the inner surface (11) of the first container wall section (6) each merge directly into the outer surface (10) and the inner surface (11) of the second container wall section (7) to form a transition rounding (44), the transition rounding (44) having a radius which originates from a radius range whose lower limit is 0.3 mm, in particular 0.5 mm, and whose upper limit is 80 mm, in particular 50 mm. 3 sheets of drawings